Ultralow-power hydrogen sensing with single palladium nanowires

P. Offermans; H. D. Tong; C. J.M. Van Rijn; P. Merken; S. H. Brongersma; M. Crego-Calama

doi:10.1063/1.3132064

Ultralow-power hydrogen sensing with single palladium nanowires

P. Offermans
, H. D. Tong
, C. J.M. Van Rijn
, P. Merken
, S. H. Brongersma
, M. Crego-Calama

Communication, Information, Systems and Sensors

Interuniversitair Micro-Electronica Centrum vzw
Nanosens BV

Publikation: Beitrag in Fachzeitschrift › Artikel › Begutachtung

152 Zitate (Scopus)

Abstract

Palladium nanowires were fabricated on silicon substrates using conventional microfabrication techniques. Sensors based on such nanowires show a reversible response to hydrogen concentrations as low as 27 ppm with response times varying from 5 s (H2 concentrations >20%) to 30 s (H2 concentrations <100 ppm) at room temperature. The response times can be reduced by increasing the applied bias due to resistive heating. The noise spectrum of the nanowires shows a 1/f behavior, sufficiently low to enables the detection of hydrogen with an ultralow-power consumption. The influence of oxygen on the nanowire response was also investigated.

Originalsprache	Englisch
Aufsatznummer	223110
Fachzeitschrift	Applied Physics Letters
Jahrgang	94
Ausgabenummer	22
DOIs	https://doi.org/10.1063/1.3132064
Publikationsstatus	Veröffentlicht - 2009

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10.1063/1.3132064

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abstract = "Palladium nanowires were fabricated on silicon substrates using conventional microfabrication techniques. Sensors based on such nanowires show a reversible response to hydrogen concentrations as low as 27 ppm with response times varying from 5 s (H2 concentrations >20\%) to 30 s (H2 concentrations <100 ppm) at room temperature. The response times can be reduced by increasing the applied bias due to resistive heating. The noise spectrum of the nanowires shows a 1/f behavior, sufficiently low to enables the detection of hydrogen with an ultralow-power consumption. The influence of oxygen on the nanowire response was also investigated.",

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AU - Offermans, P.

AU - Tong, H. D.

AU - Van Rijn, C. J.M.

AU - Merken, P.

AU - Brongersma, S. H.

AU - Crego-Calama, M.

PY - 2009

Y1 - 2009

N2 - Palladium nanowires were fabricated on silicon substrates using conventional microfabrication techniques. Sensors based on such nanowires show a reversible response to hydrogen concentrations as low as 27 ppm with response times varying from 5 s (H2 concentrations >20%) to 30 s (H2 concentrations <100 ppm) at room temperature. The response times can be reduced by increasing the applied bias due to resistive heating. The noise spectrum of the nanowires shows a 1/f behavior, sufficiently low to enables the detection of hydrogen with an ultralow-power consumption. The influence of oxygen on the nanowire response was also investigated.

AB - Palladium nanowires were fabricated on silicon substrates using conventional microfabrication techniques. Sensors based on such nanowires show a reversible response to hydrogen concentrations as low as 27 ppm with response times varying from 5 s (H2 concentrations >20%) to 30 s (H2 concentrations <100 ppm) at room temperature. The response times can be reduced by increasing the applied bias due to resistive heating. The noise spectrum of the nanowires shows a 1/f behavior, sufficiently low to enables the detection of hydrogen with an ultralow-power consumption. The influence of oxygen on the nanowire response was also investigated.

UR - https://www.scopus.com/pages/publications/66749163481

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ER -

Ultralow-power hydrogen sensing with single palladium nanowires

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